ES2209144T3 - PROCEDURE AND NETWORK COMPONENT OF A COMMUNICATIONS NETWORK FOR COMMUNICATIONS OF LOW BINARY SPEED COMMUNICATIONS BETWEEN INPUT MODULES AND OUTPUT MODULES. - Google Patents

Abstract

The invention relates to the switching of low bit rate connections between input modules and output modules of a component of a network (for example BSC, RNC, TRAU). According to the invention, the input modules (ILIC) and the output modules (OLIC) form a first switching level. At the first switching level, several low bit rate (TDM-I) connections are grouped respectively into at least one ATM via the input module (ILIC). These low bit rate connections are located in the input module (ILIC) and have to be transmitted to the same output module (OLIC). At the second switching level, the ATM switching center (ASW) guarantees the connection of ATM connections to transfer information in ATM cells. Then, at the first switching level, ATM connections are converted by the output module into the low bit rate connection (TDM-O) of at least one input module (ILIC). The combined switching at two switching levels represents a particularly economical solution for specific functions for mobile telephony, while ensuring acceptable voice quality with good use of ATM bandwidth.

Description

Procedure and network component of a network communications for low communications switching bit rate between input modules and output modules.

The invention relates to such a procedure. as to a corresponding network component for the switching of low bit rate communications between input modules and output modules of the network component of a network of communications

In communications networks - preferably mobile radio networks or fixed networks - information - for example, useful information or signaling information during voice transmission - is transported at low transmission speeds by means of multiple access procedures. Time division TDM (Time Division Multiplex) through lines between components of the network. For example, PCM30 or PCM24 connection lines can be used. For the transmission of information by cable - in fixed networks, but also in mobile radio networks, especially of the next generation - ATM (Asynchronous Transfer Mode) transmission is increasingly carried out with its advantages over the applications of broadband. Nevertheless, the transmission of narrowband information through low bit rate communications
-example, TDM communications. It remains an important application for the plurality of mobile radio or fixed network subscribers. Therefore, when a TDM multiple technique must be converted into an ATM transmission technique in a network component, a large delay usually occurs - for example 48 msec. in an 8 kbit / s voice transmission. This leads to a detriment of voice quality.

In principle, there is, in effect, a conversion TDM multiple technique in ATM transmission technique, which only leads to small delays - for example through the filling of ATM cells with only a few bytes - but this has as consequence an economical use of bandwidth ATM. For this reason, there is so far a problem to perform network components of a telecommunications network in such a way that internally distribute traffic through an installation ATM switching and at the same time support low TDM traffic bit rate on external lines.

It is known by the patent application International WO 95/17789 an ATM network for band communication narrow. PCM signals are converted - therefore, signals from multiple time division access - in ATM cells to switch them in an ATM switching facility, which features a reduced number of several switching phases. PCM data, which they can be transmitted to a common destination, they are grouped into individual STM cells.

The purpose of the present invention is to indicate a procedure and a component of the network for switching low bit rate communications on the ATM basis, to through which a time can be achieved at the same time delay as small as possible and a high degree of utilization ATM bandwidth available.

This task is solved according to the invention by through the characteristics of claims 1 and 5 of the invention with respect to the procedure and through the characteristics of claims 15 and 16 of the invention with regarding the network component. The developments of the invention are indicated in the dependent claims.

The invention starts from a switching of low bit rate communications between input modules and output modules of a network component of a network communications In this case, the input modules and modules output form a first switching plane as well as a ATM switching facility arranged between the modules input and output modules forms a background of commutation. In the first switching plane, respectively, several low bit rate communications from the module input, which are in the input module and must transmitted to one and the same output module, are grouped in at least one ATM communication. In the background of switching, is carried out from the switching installation ATM switching of ATM communications for the transmission of information in ATM cells. Then they become the close-up switching the switched ATM communications of one or several input modules in low speed communications Binary output module. According to the invention, in the modules of input and in the output modules of the first switching plane ATM lines are connected, respectively, through the which are received and transmitted information of several structured communications in a multiple table by division of time or in ATM mini-packages.

If the switching process is distributed in two planes, then several communications are transported in common in the same ATM communication, so that a reduced delay and good utilization of cell capacity ATM. Combination switching in two switching planes It represents a particularly economical solution for functions specific mobile radio, which ensures quality at the same time acceptable voice with good use of bandwidth ATM. The invention of switching several planes in one ATM switching installation and in input and output modules willing separated from it reconciles two essential aspects between yes, namely, minimize the delay through conversion of low bit rate communications in ATM technique and raise the use of ATM broadband. The concept of the decentralized switching in two planes has the advantage that Switching processes can be performed on both modules input / output modules as well as the installation of ATM switching at least of the same type or in one and the same type. In addition, it is possible in a simple and low cost way adaptation of software and hardware in the switching planes to through a switching control.

According to a development of the invention, a common control facility assumes control in both the first as also in the background. It is especially advantageous that the ATM switching facility be operated as a principle of decentralized switching, whose control installation causes settings in the input modules and in the output modules of the close-up switching. Unitary control of the planes of switching one and two can be done with reduced expense of Hardware and software.

In accordance with other advantageous configurations of the invention there are various methods, which can perform the Narrowband switching in the first switching plane. Two of these methods are based on the collection of mini-packages in ATM cells, being selected with the help of a table of communication in the input module and in the output module, respectively, which mini-packages are inserted into which ATM cell and which mini-packages are distributed on which communications of the input module The methods follow the principle of grouping in First, communications - for example, TDM communications - in common outputs and then convert them into communications of packages, which is equivalent to the registration of information in ATM cells. This way of proceeding has the advantage that you can get a delay up to five times less and at the same time at least double use of bandwidth available with respect to the two methods mentioned first place.

Two-plane switching refers to preference for low bit rate traffic communications, because they represent most of the volume of communications, but can also be applied to communications from signaling and operation and maintenance communications (O&M, Operation and Maintenance).

The invention will be explained in detail below. with the help of embodiments with reference to graphic representations In this case:

Figure 1 shows the block diagram of a network component for communication switching in two switching planes for a transmission installation of the communication.

Figures 2 and 3 show block diagrams of an input module and an output module for switching of communications in the first switching plane based on the collection of mini-packages in cells ATM.

Figures 4 and 5 show block diagrams of an input module and an output module for switching of communications in the first switching plane based on the TDM communications meeting in cells ATM.

Figure 6 shows the working mode of principle of a TDM switching element for meeting the TDM communications, which belong to the same output module, in common departures, and

Figures 7 to 9 show different principles to fill ATM cells with TDM information.

Figure 1 shows the block diagram of a network component for communication switching according to the invention in two switching planes for one direction of transmission of the communication that is continued in the figures following. The return direction extends parallel to the represented transmission address, so that they apply to they in a corresponding way the following explanations. The network component is in the example a station control Base Controller (Base Station Controller = Station Controller Base), which assumes, as part of a GSM mobile radio network or a universal telecommunication network (UMTS, Universal Mobile Telecommunication System) control and command of technical tasks radio - especially the control of base stations, or a TRAU transcoding facility (Transcoding and Rate Adaption Unit = Transcoding and adaptation unit of the Speed), which is carried out, as is known, in the radio network GSM mobile for each useful channel an adaptation of the different transmission speeds between the base station control BSC or RNC radio control and a switching center (MSC) connected in it as well as the transcoding function.

In this case, figure 1 shows the essentially identical functional structure for the components of the BSC, RNC, TRAU network for communications switching, without describing in detail the functions known per se, which are not relevant to the invention of the network component respective. A switching application is also possible. according to the invention, characterized by two switching planes, in The mobile switching center. The invention is also not limited to network components of a mobile radio network, but, in principle, supports any component of the network, which exerts specific functions of the fixed network or mobile network, such as example, switching, control, transcoding tasks, etc. and in this case internally guides the traffic through the ATM transmission technique and on external lines low traffic bit rate, for example through TDM communications.

With the invention presented it is possible, from of an ATM switching principle, perform the components of the network with the functionalities mentioned above by way of example. The component of the BSC / TNC / TRAU network presents for this purpose an ASW ATM-switching facility, which is preferably constituted by several ASM modules (ATM Switching Module = Switching Modules, for example with 5 Gbps) and several AMX ATM multiplexers. The modules of the line (Line Interface Circuits = Line Interface Circuits) and the installation of MP-CP control are connected through AMX multiplexers with the installation of ASW-ATM switching. The modules of the line assume the function of an ILIC input module or an output module OLIC, depending on whether it is arranged on the input side or on the output side on the transmission path. Therefore in principle Each module of the line includes the function of an input module ILIC and an OLIC output module. Several are grouped in each case communications on the TDM-I input side of ILIC input modules and are transmitted through the AMX multiplexers in address I in the example shown towards The ASW ATM-switching facility. Efficiency of narrowband multiplexing over the input modules ILIC can be raised because a high number of TDM-I communications, for example eight Communications for each module.

The ATM switching facility ASW forms in this case the second of the two switching planes according to the invention, operating according to the switching principle decentralized, in which the communication channels are established  through communication tables in the ILIC input modules and on the OLIC output modules, which are connected on the side of entrance and exit side, respectively, with the installation ASW-ATM switching. ILIC input modules and the OLIC output modules form the first of the two planes of switching according to the invention. In the foreground switching several communications are grouped respectively TDM-I low bit rate, found in each of the two ILIC input modules represented and that must be transmitted to the same OLIC output module (marked with thick arrows), from the respective ILIC input module towards at least one ATM communication. In this case, the lines external - such as the PCM 30 lines - drive the TDM-I communications information unsubscribe bit rate, which are contained, according to the procedure Multiple TDM in several time divisions of a TDM frame.

In the background switching takes out from the ASW-ATM switching facility the ATM communications switching for the transmission of information in ATM cells. Then they become the close-up switching ATM communications switched to OLIC output module, which come from one or more modules of ILIC input, in low TDM-O communications bit rate from the OLIC output module. If it is distributed, according to the invention, the two-plane switching process, then one or more TDM communications are transported from the side of input of a common ILIC input module in it ATM communication and associate on the output side in a way correct to one of the OLIC output modules, so that they result as advantages a reduced delay and a good use of the ATM cell capacity. They can also be brought together several ATM communications from different ILIC input modules in the same OLIC output module. The commutation combined in two switching planes represents a solution especially economic, which ensures at the same time an acceptable quality of the voice with good use of ATM bandwidth. The invention of switching in several planes in an installation of ATM switching and in input modules and output modules ILIC and OLIC arranged separately from each other harmonizes two aspects opposites, namely minimizing the delay through the conversion of low bit rate communications into technique ATM and increase the use of ATM bandwidth. The concept of decentralized switching in two planes has the advantage that switching processes can be performed both in the input modules / output modules as well as in the ASW switching installation at least of the same type or of one and the same way. These two-plane switching procedures they can also be applied when the input modules and the ILIC and OLIC output modules are connected on ATM lines external, which transmit the information in a structured way either in the TDM frame structure or as mini-cells (according to AAL 2, ATM Adaption Layer 2 = Adaptation Layer Mini Cells two).

Control facilities for treatment of communication (call processing) may be different from control facilities for signaling tasks or O&M (Operation and Maintenance). The work of switching of the first switching plane and the second plane of switching is assumed by the control facility MP-CP (Main Processor for Call Processing = Main Processor for the Treatment of Communication) that is coupled with the ATM switching facility. This has the advantage that due to the principle of decentralized switching, the MP-CP control installation only has to make adjustments to the input modules and the modules ILIC and OLIC output, to perform both foreground control as also from the background. If left autonomously any of the three switching units, therefore of agreement with a network of switching nodes, then three control facilities should coordinate their actions in each communication through signaling. This is eliminated through a processor, which performs the entire control task. East unit control can be performed with a reduced cost of hardware and software and, if necessary, can be adapted in one Simple and inexpensive way to modifications.

In the case of component configuration of the network as a base station control / radio control BSC / RNC with additional functionality, consisting of support of a data transmission according to a packet data service GPR (General Packet Radio System = General Radio System by Packages), the layout can be completed with an installation SPU (Signal Processing Unit = Signal Processing Unit) (represented with dots and strokes). The SPU installation, which is also connected through an AMX multiplexer in the module ASM, has a line module, which converts ATM cells that arrive as an OLIC output module in TDM communications TDM-O and convert TDM communications TDM-I entering as an ILIC input module in ATM cells In addition, the SPU installation features a processor DSP digital signals for the treatment of functions oriented to TDM -in the framework of the GPRS service- on the basis of information contained in TDM communications. In the case of that the GPRS service be controlled by the station control Based on BSC or by RNC radio control, communication is extends first from an ILIC input module (arrow I thick marked) through the ASW ATM switching facility until installation SPU (arrow II marked thick) and after Signal processing extends from the SPU installation (arrow II marked thick) again through the installation of ATM ASW switching to the OLIC output module. In the case of application of the invention on an installation of TRAU transcoding as a network component is applied in a corresponding manner as explained above, where the SPU installation is not optionally connected based on a additional functionality but is always connected in the path of transmission. In this case, it is operated as a module transcoding for performing functions of transcoding

An alternative to the double execution of the ASW ATM switching facility for the mentioned purposes previously it is that the ILIC and SPU facilities are they can substitute on the transmission path II for a single SPU installation It also has a signal processor DSP digital for TDM signal processing as well as a guide module with the functionality of an ILIC input module, so that information about TDM communications TDM-I on the input side can be processed immediately before conversion to ATM cells continues and switching through the ASW ATM switching facility (arrow II marked thick) towards the OLIC output module.

Figures 2 and 3 show block diagrams of an ILIC input module and an OLIC output module for the switching of communications in the first switching plane based on the collection of mini-packages in ATM cells. The Figure 2 shows the route of transmission of information in the ILIC input module from communications TDM-I arriving at the entrance side until ATM cells that leave on the output side, which are transmitted towards the ATM switching facility. In a similar way to this, figure 3 shows the way of transmission of the information in the OLIC output module from the ATM cells arriving in the input side to TDM-O communications that They leave from the exit side.

From the incoming TDM bit stream it is form mini-packages and accumulate in mini-package collectors MPC, being available for each communication - for example Useful communication for voice transmission - a compiler of MPC mini-packages of this type. The mini-packages are constituted by a package header and by a package trunk. The header The mini-package contains at least the communication address for the definition of the respective communication. Additionally they can be contained security fields, indications about the mini-package length, sequence numbers, etc. On the trunk the data of the communication is contained, which must be transmitted The trunk of the mini-package is formed by collecting from each incoming TDM frame those time divisions, that belong to the respective voice communications. The length of the trunk is some bytes. In this way, the delay time It is as small as in partially filled ATM cells. Since it is possible to accommodate several mini-packages at the same time an ATM cell, you get the advantage of a use improved transport capacity of ATM cells. With preference, the format of the package header of the Mini packages may be different. Or it is a format proprietary, so that the smallest possible number of bits or of the format that has been established in the Standard for AAL 2. The reduced number of bits in the proprietary format is possible when a fixed length of the trunk is selected and bits of test sums, since the first switching plane is insured anyway.

From the accumulated mini-packages you can then grouping ATM cells into ATM ACC cell collectors. In a table of the CONT1 communication establishes which mini-package belongs to which ATM ACC cell collector. The tickets and the deleted in this table are assumed by the control processor according to figure 1 during the establishment and interruption of the  communication. In parallel with this it still processes the other table of  CONT2 communications in the ILIC input module, the table of CONT2 'symmetric communications on the OLIC output module (Figure 3) and its CONT1 'communications table. Through processing of the communication table CONT1 or CONT1 'is controls the first plane of the switching, through the processing of the CONT communications table or CONT2 'se controls the background of the switching. For switching from the switching background, the control processor sets in the CONT2 communications table of the ILIC input module for each ATM ACC cell collector to which OLIC output module should Get your ATM cells. Information about the output module respective OLIC is deleted in the header of the ATM cell. The ATM cells leave the ATM ACC cell collectors when they It meets at least one of two conditions. Or the ATM cell is full, or has reached the maximum allowable fill time. Should observe the allowable filling time because the mini-packages they must reach the receiver within a swing width determined delay, but at the same time is not guaranteed that a sufficient number of MPC packet accumulators handle the ATM ACC cell collector, to fill the ATM cell with a fast enough way.

After leaving the ATM cell collector ACC, ATM cells go through a DEL delay facility, configured in the simplest case as delay members parallel to ATM cells emitted from the collectors of ACC ATM cells, with random propagation time. In this way it prevents all ATM ACC cell collectors from the module from ILIC input at the same time empty your ATM cells in a memory of ATM ACC cells connected downstream, from which it is performed additional transport to the ASW ATM switching facility. There is a threat of simultaneous expulsion of ATM cells when, at the beginning of the TDM transmission, all lines TDM external devices, which are connected to the ILIC input module, are synchronized both with respect to the clock pulse and also to the TDM frame phase. When ATM cell memory ACB is not large enough, cells can be lost or may exceed the maximum permissible oscillation width of the delay. Therefore, the DEL delay installation is connected with random propagation time between cell collectors ATM and ACB ATM cell memory.

On the OLIC output module converge usually several ATM communications of different modules of ILIC entry - for example those represented in Figure 1-, switched by the ASW switching facility. In a memory of ATM cells on the ACB input side accumulate ATM cells corresponding. With the help of the information contained in the ATM cell header is determined from which input module ILIC which ATM cells come from, and through the table of CONT2 'communication ATM cells are distributed over several MPG mini-pack generators. From ATM cells it detach the mini-packages in each MPG mini-pack generator and they are stored in an intermediate way in mini-pack accumulators connected below. From there a conversion of mini-packages in communications TDM-O with TDM bitstream, so that the  content of the mini-packages is switched on the output line respective external connected to the time division correspondent. An information in the header of the package of Mini cells provide the right destination. The table of CONT1 'communication on the OLIC output module deals with the correct association between mini-packages and accumulators of MPC mini packs.

In principle, ATM communication is sufficient individual to transport all communications from mini-packages from the ILIC input module to a module OLIC output determined, although TDM communications on the side of input and TDM communications on the output side differ locally In order to differentiate communications from mini-packages with each other, preferably a space of sufficiently large addresses, which can be addressed to through the header of the mini package. In the AAL 2 procedure standardized 248 addresses are available mini cells If they are sold out, another ATM communication is established between the input module and the output module. As an alternative to this you can also design the address space much more great thanks to the proprietary format, and you save the expense for the installation of other ATM communications.

Figures 4 and 5 show block diagrams of an ILIC input module and an OLIC output module for the commutation of communications in the foreground of the switching based on the TDM communications pool in ATM cells While the procedure according to figures 2 and 3 follow the principle of packaging byte by byte communications TDM, in the example according to figures 4 and 5, these are processed bit per bit This has the advantage that the delay time is exactly as low as in the conventional case oriented to the line (switched circuit). At the same time, the use of the available bandwidth is at least double that in the mode proceed according to figures 2 and 3, since for identification of narrowband communication is not necessary no header of the mini-package but the position in the TDM box. Narrowband switching over the ILIC input module as above the OLIC output module use a change of time layers and a change of layers of space, whose result is again TDM frames. This task is assumed by a TDM BSW switching element (Bit Switch = bit switching), which is able to switch TDM-I low bit rate communications, which they are located on the input side in the input module, in the output side to TDM-O 'low communications bit rate and communications switching TDM-I 'low bit rate, found on the input side on the OLIC output module, on the side of output in low speed TDM-O communications binary

Specifically, this means according to the representation of figure 6, that the TDM switching element BSW can switch each individual bit of a TDM frame TDM-FR, divided into TCHB communication bits and bits SYNB synchronization. For example, in the PCM transmission you It represents an 8kbit / sec channel. through a respective bit by PCM table (cycle time of table 125 \ museg.).

According to figure 4, the information of the binary current, conditioned by the switching element TDM BSW, are grouped in ATM ACC cell collectors connected downstream to form ATM cells, which are inscribed to continuation in ACB ATM cell memory - with the help of the CONT2 communication table for switching the (s) ATM communication (s) in the ATM switching facility ASW-. Therefore, the second stage to be carried out in the module ILIC input after multiplexing of TDM communications it consists of packaging the information conducted by the TDM communications at the outputs of the TDM switching element BSW in ATM cells. For this second stage there are principles alternatives, which are represented in figures 7 to 9.

According to figure 5, on the OLIC output module ATM communications come back from different modules ILIC input, switched over switching installation ASW In the ACB ATM cell memory on the input side it accumulate the corresponding ATM cells. From there, the cells ATM reach the respective ATM cell collectors, where carries out the association through the communication table CONT2 ', used for switching the (s) ATM communication (s), in the OLIC output module. TO then an unpacking of ATM cells is executed, that come from the ATM cell collectors, so that feed parallel binary streams of information to respective TDM TDM-I communications on the side of TDM BSW switching element input and are switched according  with the representation of figure 6 towards TDM communications on the output side to the OLIC output module.

Figures 7 to 9 show different principles for filling ATM cells with information on TDM communications. All the representations have in common that from the respective input of the TDM BSW switching element, one or more TDM TDM-FR frames with the TCHB communication bits and the SYN synchronization bits and are inscribed as ATM-C ATM cells in memory ATM cells and from there they are transmitted to the ATM switching facility. Each ATM-ATM ATM cell has, as is known, an AHD header field and a data field.
ADFAT

In Figure 7, the bits that arrive from the TDM output are enrolled, according to the series, in the ATM cell ATM-C. As soon as the ATM cell ATM-C is full, it is sent. Not so much not it matters if a bit belongs to a TDM communication to useful information or for signaling information from the TCHB communication bits, or from the bits SYNB synchronization of TDM TDM-FR panel. By therefore, there is no relationship between the phase of the TDM table and the position of the TDM information in the ATM cell. In this method, packaging TDM boxes in ATM cells is simple and all available ATM bandwidth is used.

In an alternative method according to figure 8 are packaged, by means of AAL1 (ATM Adaption Layer 1 = Layer of Adaptation 1) all TDM time divisions outside the division of synchronization time in ATM cells. For what the receiving side can recognize the position of the divisions of TDM time inside the ATM cell, it is inserted into one of each eight ATM cells additionally a POI pointer, which refers to the beginning of the TDM structure, which can be recognized in the first CB0 information byte. For this case, ATM cells ATM-C are designated as "cells Structured AAL-1 ". The AAL1 procedure It plans to transmit ATM cells periodically. In this case, the period is tuned to the speed of the output data TDM, so that each ATM cell is completely filled. From this way, this method takes advantage of ATM bandwidth available and facilitates synchronization next to reception ATM.

In another alternative method according to Figure 9, each ATM-C ATM cell has exactly one TDM TDM-FR frame. This one is placed in the cell ATM ATM-C so that it can be found Always a SYNB sync byte in the same place. Too in this method ATM cells are transmitted periodically and the packaging process takes into account the structure of TDM frames. Therefore, the width of ATM band, but TDM synchronization can be performed well ATM reception side and it works in the same way to PCM30 and PCM24 connection lines to support communications Binary low speed TDM.

Claims (20)

1. Procedure for switching low bit rate communications between input modules (ILIC) and output modules (OLIC) of a network component (for example, BSC, RNC, TRAU) of a communications network, in the what

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the modules of input (ILIC) and output modules (OLIC) form a first communication plane,

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an installation of ATM switching (ASW), arranged between the input modules (ILIC) and the output modules (OLIC), forms a background of commutation,

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in the foreground switching, respectively, several communications (TDM-I) low bit rate, found in the input module (ILIC) and must be transmitted to it Output module (OLIC) are combined by the input module (ILIC) to form at least one ATM communication,

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In the background switching, ATM communication is switched by the installation ATM switching (ASW) for the transmission of information in ATM cells, and

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in the foreground switching, switched ATM communications of one or more input modules (ILIC) are transformed by the output module (LIC) in low bit rate communications (TDM-O),

characterized because in the input modules (ILIC) and in the modules Output (OLIC) of the first switching plane are connected, respectively, external ATM lines, through which they are received and transmitted information from various communications, structured in ATM mini-packages, being accumulated, respectively, mini-packages in the input modules (ILIC) of communication foreground and ATM cells being formed from of the accumulated mini-packages, being selected with the help of a communication table (CONT1) which mini-packages are inserted in which ATM cells. 2. Method according to claim 1, in the that ATM cells go through a delay facility (DEL), which works with random propagation time, of the module input (ILIC), before they are temporarily stored in an ATM cell memory (ACB) and are transmitted to the ATM switching facility (ASW) in the background of commutation. 3. Method according to claim 1 or 2, in which the mini-packages present, respectively, a header package with at least one communication address, for which a property header format or a format of normalized header. 4. Procedure according to one of the previous claims, wherein for the switching of the communications in the output modules (OLIC) of the foreground of switching accumulate, respectively, ATM cells and generate and mini-packages are temporarily memorized from the cells ATM, being selected with the help of a communication table (CONT1 ') which mini-packages are distributed on which communications of the output module (OLIC). 5. Procedure for switching low bit rate communications between input modules (ILIC) and output modules (OLIC) of a network component (for example, BSC, RNC, TRAU) of a communications network, in the what

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the modules of input (ILIC) and output modules (OLIC) form a first communication plane,

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an installation of ATM switching (ASW), arranged between the input modules (ILIC) and the output modules (OLIC), forms a background of commutation,

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in the foreground switching, respectively, several communications (TDM-I) low bit rate, found in the input module (ILIC) and must be transmitted to it Output module (OLIC) are combined by the input module (ILIC) to form at least one ATM communication,

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In the background switching, ATM communication is switched by the installation ATM switching (ASW) for the transmission of information in ATM cells, and

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in the foreground switching, switched ATM communications of one or more input modules (ILIC) are transformed by the output module (LIC) in low bit rate communications (TDM-O),

characterized because in the input modules (ILIC) and in the modules Output (OLIC) of the first switching plane are connected, respectively, external ATM lines, through which they are received and transmitted information from various communications, structured in multiple access tables by time division, where in the input modules (ILIC) and in the output modules (OLIC), respectively, of the foreground of communication are multiplexed and demultiplexed, respectively, the communications (TDM-I, TDM-I ') a through a switching element (BSW), where with the help of a communication table (CON1, CONT1 ') is carried out a association of communications to exits. 6. Method according to claim 5, in the that in the input modules (ILIC) cells are formed and accumulated ATM based on multiplexed information at the outputs common, before they are temporarily stored in a memory ATM cells (ACB) and be sent to the installation of ATM switching (ASW) of the switching background. 7. Method according to claim 5 or 6, in which ATM cells that arrive at the output modules (OLIC) of the first switching plane are stored temporarily in an ATM cell memory (ACB) and then are accumulated, before they are fed to the switching element (BSW). 8. Procedure according to one of the previous claims, wherein with the help of another table of communication (CONT2) in the input module (ILIC) is select which ATM cells are switched to which output module (OLIC) for the background ATM switching (ASW) installation switching 9. Procedure according to one of the previous claims, wherein with the help of another table communication (CONT2 ') in the output module (OLIC) is select which ATM cells are distributed to which collector of ATM cells (ACC) or to which mini-package generator (MPG). 10. Procedure according to one of the claims 6 to 9, wherein the ATM cells (ATM-C) are filled in such a way that the information that arrives at a common exit is registered in series and consecutively in the ATM cell (ATM-C), regardless of whether it is useful information or signaling information. 11. Procedure according to one of the claims 6 to 9, wherein the ATM cells (ARM-C), as structured ATM cells, are filled with the information that arrives at a common exit, which contains a pointer (POI) for the identification of the beginning of the structure. 12. Procedure according to one of the claims 6 to 9, wherein the ATM cells (ATM-C) are filled, in part, with the information that arrives at a common exit and contains, respectively, synchronization information found In the same place. 13. Procedure according to one of the previous claims, wherein an installation is used of control (MP-CP) common for the control of functions in the first and second switching planes. 14. Procedure according to one of the previous claims, wherein the installation of ATM switching (ASW) is operated as a principle of decentralized switching, whose control facility (MP-CP) causes adjustments to the input modules (ILIC) and in the output modules (OLIC) of the foreground of commutation. 15. Network component (for example, BSC, RNC, TRAU) for low speed communications switching Binary between input modules (ILIC) and output modules (OLIC) of a network component (for example, BSC, RNC, TRAU) of a network communications, with

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a close-up of switching formed by the input modules (ILIC) and the modules output (OLIC),

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facilities in the input module (ILIC) of the first switching plane, respectively, for a combination of several communications (TDM-I) low bit rate, found in the input module (ILIC) and that must be transmitted to the same output module (OLIC), to form at least one ATM communication,

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a background of switching formed by an ATM switching facility (ASW) arranged between the input modules (ILIC) and the modules output (OLIC), for switching ATM communications to the transmission of information in ATM cells, and

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facilities in the output module (OLIC) of the first switching plane for the ATM communications conversion, switched in the module output (OLIC), of one or several input modules (ILIC), at low bit rate communications (TDM-O),

characterized because in the input modules (ILIC) and in the modules Output (OLIC) of the first switching plane are connected, respectively, external ATM lines for the emission and reception structured information of several communications in a table multiple access by time division, where in the modules input (ILIC) and output modules (OLIC), respectively, of the foreground switching, communications (TDM-I, TDM-I ') are multiplexed and demultiplexed through a switching element (BSW), where It can be done with the help of a communication table (CONT1, CONT1 ') an association of communications to outputs. 16. Network component (for example, BSC, RNC, TRAU) for low speed communications switching Binary between input modules (ILIC) and output modules (OLIC) of a network component (for example, BSC, RNC, TRAU) of a network communications, with

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a close-up of switching formed by the input modules (ILIC) and the modules output (OLIC),

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facilities in the input module (ILIC) of the first switching plane, respectively, for a combination of several communications (TDM-I) low bit rate, found in the input module (ILIC) and that must be transmitted to the same output module (OLIC), to form at least one ATM communication,

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a background of switching formed by an ATM switching facility (ASW) arranged between the input modules (ILIC) and the modules output (OLIC), for switching ATM communications to the transmission of information in ATM cells, and

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facilities in the output module (OLIC) of the first switching plane for the ATM communications conversion, switched in the module output (OLIC), of one or several input modules (ILIC), at low bit rate communications (TDM-O),

characterized because in the input modules (ILIC) and in the modules Output (OLIC) of the first switching plane are connected, respectively, external ATM lines for the emission and reception structured information of several communications in a table multiple access by time division, where in the modules input (ILIC) of the first switching plane can be accumulated, respectively, mini-packages and ATM cells can be formed at from the accumulated mini-packages, where you can select with the help of a communication table (CONT1), what mini-packages They are inserted into which ATM cell. 17. Network component according to claim 15 or 16, for the performance of a specific radio function mobile. 18. Network component according to claim 15, 16 or 17, configured as a control station installation base (for example, BSC) or as a radio control (for example, RNC) for the control of base stations of a radio network mobile. 19. Network component according to claim 15, 16 or 17, configured as a transcoding facility (for example, TRAU) of a mobile radio network. 20. Network component according to claim 15 or 16, to perform a specific network function fixed.